+Fix multiple bugs when MEKE_GM_SRC_ALT is True

  Fix several bugs when MEKE_GM_SRC_ALT is True, including corrections to two
dimensional rescaling factors, and optionally fix a bug that sets a limit only
on positive slopes but leaving negative slopes unlimited.  This bug is corrected
when the new runtime parameter MEKE_GM_SRC_ALT_SLOPE_BUG is false.  Additionally
there is a new runtime parameter MEKE_GM_SRC_ANSWER_DATE that specifies the use
of rotationally symmetric expressions for PE_release_h when it is set to
20240601 or higher, but it should be noted that rotational symmetry also
requires that MEKE_GM_SRC_ALT_SLOPE_BUG is false.  Four new checksum calls were
also added to verify the correctness of the calculation of MEKE%GM_src when
MEKE_GM_SRC_ALT and DEBUG are true.  By default, all answers are bitwise
identical but there are two new runtime parameters in some MOM_parameter_doc
files.

src/parameterizations/lateral/MOM_thickness_diffuse.F90

@@ -82,7 +82,14 @@ module MOM_thickness_diffuse
                                  !! used for MEKE [H ~> m or kg m-2].  When the total depth is less
                                  !! than this, the diffusivity is scaled away.
   logical :: GM_src_alt          !< If true, use the GM energy conversion form S^2*N^2*kappa rather
-                                 !! than the streamfunction for the GM source term.
+                                 !! than the streamfunction for the GM source term for MEKE.
+  integer :: MEKE_src_answer_date  !< The vintage of the expressions in the GM energy conversion
+                                 !! calculation when MEKE_GM_SRC_ALT is true.  Values below 20240601
+                                 !! recover the answers from the original implementation, while higher
+                                 !! values use expressions that satisfy rotational symmetry.
+  logical :: MEKE_src_slope_bug  !< If true, use a bug that limits the positive values, but not the
+                                 !! negative values, of the slopes used when MEKE_GM_SRC_ALT is true.
+                                 !! When this is true, it breaks rotational symmetry.
   logical :: use_GM_work_bug     !< If true, use the incorrect sign for the
                                  !! top-level work tendency on the top layer.
   real :: Stanley_det_coeff      !< The coefficient correlating SGS temperature variance with the mean
@@ -635,12 +642,12 @@ subroutine thickness_diffuse_full(h, e, Kh_u, Kh_v, tv, uhD, vhD, cg1, dt, G, GV
                   ! interface of a layer that is within a layer [nondim]. 0<h_frac<=1
   real :: dz(SZI_(G),SZJ_(G),SZK_(GV)) ! Height change across layers [Z ~> m]
   real, dimension(SZI_(G),SZJB_(G),SZK_(GV)+1) :: &
-    Slope_y_PE, &  ! 3D array of neutral slopes at v-points, set equal to Slope (below) [nondim]
+    Slope_y_PE, &  ! 3D array of neutral slopes at v-points, set equal to Slope (below) [Z L-1 ~> nondim]
     hN2_y_PE       ! Harmonic mean of thicknesses around the interfaces times the buoyancy frequency
                    ! at v-points with unit conversion factors [H L2 Z-2 T-2 ~> m s-2 or kg m-2 s-2],
                    ! used for calculating the potential energy release
   real, dimension(SZIB_(G),SZJ_(G),SZK_(GV)+1) :: &
-    Slope_x_PE, &  ! 3D array of neutral slopes at u-points, set equal to Slope (below) [nondim]
+    Slope_x_PE, &  ! 3D array of neutral slopes at u-points, set equal to Slope (below) [Z L-1 ~> nondim]
     hN2_x_PE       ! Harmonic mean of thicknesses around the interfaces times the buoyancy frequency
                    ! at u-points  with unit conversion factors [H L2 Z-2 T-2 ~> m s-2 or kg m-2 s-2],
                    ! used for calculating the potential energy release
@@ -998,7 +1005,13 @@ subroutine thickness_diffuse_full(h, e, Kh_u, Kh_v, tv, uhD, vhD, cg1, dt, G, GV
                     int_slope_u(I,j,K) * ((e(i+1,j,K)-e(i,j,K)) * G%IdxCu(I,j))
             slope2_Ratio_u(I,K) = (1.0 - int_slope_u(I,j,K)) * slope2_Ratio_u(I,K)
 
-            Slope_x_PE(I,j,k) = MIN(Slope,CS%slope_max)
+            if (CS%MEKE_src_slope_bug) then
+              Slope_x_PE(I,j,k) = MIN(Slope, CS%slope_max)
+            else
+              Slope_x_PE(I,j,k) = Slope
+              if (Slope > CS%slope_max) Slope_x_PE(I,j,k) = CS%slope_max
+              if (Slope < -CS%slope_max) Slope_x_PE(I,j,k) = -CS%slope_max
+            endif
             if (CS%id_slope_x > 0) CS%diagSlopeX(I,j,k) = Slope
 
             ! Estimate the streamfunction at each interface [H L2 T-1 ~> m3 s-1 or kg s-1].
@@ -1313,7 +1326,13 @@ subroutine thickness_diffuse_full(h, e, Kh_u, Kh_v, tv, uhD, vhD, cg1, dt, G, GV
                     int_slope_v(i,J,K) * ((e(i,j+1,K)-e(i,j,K)) * G%IdyCv(i,J))
             slope2_Ratio_v(i,K) = (1.0 - int_slope_v(i,J,K)) * slope2_Ratio_v(i,K)
 
-            Slope_y_PE(i,J,k) = MIN(Slope,CS%slope_max)
+            if (CS%MEKE_src_slope_bug) then
+              Slope_y_PE(i,J,k) = MIN(Slope, CS%slope_max)
+            else
+              Slope_y_PE(i,J,k) = Slope
+              if (Slope > CS%slope_max) Slope_y_PE(i,J,k) = CS%slope_max
+              if (Slope < -CS%slope_max) Slope_y_PE(i,J,k) = -CS%slope_max
+            endif
             if (CS%id_slope_y > 0) CS%diagSlopeY(I,j,k) = Slope
 
             Sfn_unlim_v(i,K) = -((KH_v(i,J,K)*G%dx_Cv(i,J))*Slope)
@@ -1550,14 +1569,33 @@ subroutine thickness_diffuse_full(h, e, Kh_u, Kh_v, tv, uhD, vhD, cg1, dt, G, GV
   enddo ; enddo ; endif
 
   if (find_work .and. CS%GM_src_alt) then ; if (allocated(MEKE%GM_src)) then
-    do j=js,je ; do i=is,ie ; do k=nz,1,-1
-      PE_release_h = -0.25 * (GV%H_to_RZ*US%L_to_Z**2) * &
+    if (CS%MEKE_src_answer_date >= 20240601) then
+      do j=js,je ; do i=is,ie ; do k=nz,1,-1
+        PE_release_h = -0.25 * GV%H_to_RZ * &
+                         ( (KH_u(I,j,k)*(Slope_x_PE(I,j,k)**2) * hN2_x_PE(I,j,k) + &
+                            Kh_u(I-1,j,k)*(Slope_x_PE(I-1,j,k)**2) * hN2_x_PE(I-1,j,k)) + &
+                           (Kh_v(i,J,k)*(Slope_y_PE(i,J,k)**2) * hN2_y_PE(i,J,k) + &
+                            Kh_v(i,J-1,k)*(Slope_y_PE(i,J-1,k)**2) * hN2_y_PE(i,J-1,k)) )
+        MEKE%GM_src(i,j) = MEKE%GM_src(i,j) + PE_release_h
+      enddo ; enddo ; enddo
+    else
+      do j=js,je ; do i=is,ie ; do k=nz,1,-1
+        PE_release_h = -0.25 * GV%H_to_RZ * &
                            (KH_u(I,j,k)*(Slope_x_PE(I,j,k)**2) * hN2_x_PE(I,j,k) + &
                             Kh_u(I-1,j,k)*(Slope_x_PE(I-1,j,k)**2) * hN2_x_PE(I-1,j,k) + &
                             Kh_v(i,J,k)*(Slope_y_PE(i,J,k)**2) * hN2_y_PE(i,J,k) + &
                             Kh_v(i,J-1,k)*(Slope_y_PE(i,J-1,k)**2) * hN2_y_PE(i,J-1,k))
-      MEKE%GM_src(i,j) = MEKE%GM_src(i,j) + PE_release_h
-    enddo ; enddo ; enddo
+        MEKE%GM_src(i,j) = MEKE%GM_src(i,j) + PE_release_h
+      enddo ; enddo ; enddo
+    endif
+    if (CS%debug) then
+      call hchksum(MEKE%GM_src, 'MEKE%GM_src', G%HI, scale=US%RZ3_T3_to_W_m2*US%L_to_Z**2)
+      call uvchksum("KH_[uv]", Kh_u, Kh_v, G%HI, scale=US%L_to_m**2*US%s_to_T, &
+                    scalar_pair=.true.)
+      call uvchksum("Slope_[xy]_PE", Slope_x_PE, Slope_y_PE, G%HI, scale=US%Z_to_L)
+      call uvchksum("hN2_[xy]_PE", hN2_x_PE, hN2_y_PE, G%HI, scale=GV%H_to_mks*US%L_to_Z**2*US%s_to_T**2, &
+                    scalar_pair=.true.)
+    endif
   endif ; endif
 
   if (CS%id_slope_x > 0) call post_data(CS%id_slope_x, CS%diagSlopeX, CS%diag)
@@ -2224,9 +2262,25 @@ subroutine thickness_diffuse_init(Time, G, GV, US, param_file, diag, CDp, CS)
                  "If true, write out verbose debugging data.", &
                  default=.false., debuggingParam=.true.)
 
+  call get_param(param_file, mdl, "DEFAULT_ANSWER_DATE", default_answer_date, &
+                 "This sets the default value for the various _ANSWER_DATE parameters.", &
+                 default=99991231, do_not_log=.true.)
+
   call get_param(param_file, mdl, "MEKE_GM_SRC_ALT", CS%GM_src_alt, &
                  "If true, use the GM energy conversion form S^2*N^2*kappa rather "//&
                  "than the streamfunction for the GM source term.", default=.false.)
+  call get_param(param_file, mdl, "MEKE_GM_SRC_ANSWER_DATE", CS%MEKE_src_answer_date, &
+                 "The vintage of the expressions in the GM energy conversion calculation when "//&
+                 "MEKE_GM_SRC_ALT is true.  Values below 20240601 recover the answers from the "//&
+                 "original implementation, while higher values use expressions that satisfy "//&
+                 "rotational symmetry.", &
+                 default=20240101, do_not_log=.not.CS%GM_src_alt) ! ### Change default to default_answer_date.
+  call get_param(param_file, mdl, "MEKE_GM_SRC_ALT_SLOPE_BUG", CS%MEKE_src_slope_bug, &
+                 "If true, use a bug that limits the positive values, but not the negative values, "//&
+                 "of the slopes used when MEKE_GM_SRC_ALT is true.  When this is true, it breaks "//&
+                 "all of the symmetry rules that MOM6 is supposed to obey.", &
+                 default=.true., do_not_log=.not.CS%GM_src_alt) ! ### Change default to False.
+
   call get_param(param_file, mdl, "MEKE_GEOMETRIC", CS%MEKE_GEOMETRIC, &
                  "If true, uses the GM coefficient formulation from the GEOMETRIC "//&
                  "framework (Marshall et al., 2012).", default=.false.)
@@ -2238,9 +2292,6 @@ subroutine thickness_diffuse_init(Time, G, GV, US, param_file, diag, CDp, CS)
                  "The nondimensional coefficient governing the efficiency of the GEOMETRIC "//&
                  "thickness diffusion.", units="nondim", default=0.05)
 
-    call get_param(param_file, mdl, "DEFAULT_ANSWER_DATE", default_answer_date, &
-                 "This sets the default value for the various _ANSWER_DATE parameters.", &
-                 default=99991231)
     call get_param(param_file, mdl, "MEKE_GEOMETRIC_ANSWER_DATE", CS%MEKE_GEOM_answer_date, &
                  "The vintage of the expressions in the MEKE_GEOMETRIC calculation.  "//&
                  "Values below 20190101 recover the answers from the original implementation, "//&